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Explainable extreme gradient boosting tree-based prediction of load-carrying capacity of FRP-RC columns
Highlights Development of an XGBoost predictive model of maximum axial load-carrying capacity of FRP-RC columns. Interpretation of XGBoost prediction model using SHAP values. Verification of XGBoost prediction model with empirical and code-based models. Demonstration of the capability of machine learning models to predict the axial load-carrying capacity of FRP-RC columns.
Abstract This study presents a new approach for predicting the load-carrying capacity of reinforced concrete (RC) columns reinforced with fiber-reinforced polymer (FRP) bars with an eXtreme Gradient Boosting (XGBoost) algorithm. The proposed XGBoost model was developed based on a comprehensive database containing experimental data for 283 FRP-RC columns collected from the literature. The SHapley Additive exPlanations (SHAP) framework was used to interpret the output of the model. Furthermore, the efficiency and accuracy of the XGBoost model were evaluated and compared with design codes and equations in the literature. The results show that the proposed prediction model performed extremely well and was suitable for predicting the load-carrying capacity of FRP-RC columns. Moreover, the XGBoost model outperformed other numerical equations. For short columns, the mean R2 and MAPE values for the XGBoost model were 0.98% and 5.3%, respectively. In addition, the most significant input variables for predicting the maximum axial load-carrying capacity of FRP-RC columns were the eccentricity ratio, gross sectional area, compressive strength of concrete, slenderness ratio, and spacing or pitch of transversal reinforcement. Lastly, this study demonstrates the capability of machine learning models to predict the axial load-carrying capacity of FRP-RC columns. The proposed XGBoost model can provide an alternative method to existing mechanics-based models for design practice.
Explainable extreme gradient boosting tree-based prediction of load-carrying capacity of FRP-RC columns
Highlights Development of an XGBoost predictive model of maximum axial load-carrying capacity of FRP-RC columns. Interpretation of XGBoost prediction model using SHAP values. Verification of XGBoost prediction model with empirical and code-based models. Demonstration of the capability of machine learning models to predict the axial load-carrying capacity of FRP-RC columns.
Abstract This study presents a new approach for predicting the load-carrying capacity of reinforced concrete (RC) columns reinforced with fiber-reinforced polymer (FRP) bars with an eXtreme Gradient Boosting (XGBoost) algorithm. The proposed XGBoost model was developed based on a comprehensive database containing experimental data for 283 FRP-RC columns collected from the literature. The SHapley Additive exPlanations (SHAP) framework was used to interpret the output of the model. Furthermore, the efficiency and accuracy of the XGBoost model were evaluated and compared with design codes and equations in the literature. The results show that the proposed prediction model performed extremely well and was suitable for predicting the load-carrying capacity of FRP-RC columns. Moreover, the XGBoost model outperformed other numerical equations. For short columns, the mean R2 and MAPE values for the XGBoost model were 0.98% and 5.3%, respectively. In addition, the most significant input variables for predicting the maximum axial load-carrying capacity of FRP-RC columns were the eccentricity ratio, gross sectional area, compressive strength of concrete, slenderness ratio, and spacing or pitch of transversal reinforcement. Lastly, this study demonstrates the capability of machine learning models to predict the axial load-carrying capacity of FRP-RC columns. The proposed XGBoost model can provide an alternative method to existing mechanics-based models for design practice.
Explainable extreme gradient boosting tree-based prediction of load-carrying capacity of FRP-RC columns
Bakouregui, Abdoulaye Sanni (author) / Mohamed, Hamdy M. (author) / Yahia, Ammar (author) / Benmokrane, Brahim (author)
Engineering Structures ; 245
2021-07-08
Article (Journal)
Electronic Resource
English
Load carrying capacity of simple composite columns
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Load Carrying Capacity of Thin-Walled Short Columns
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